US7375534B2 - Method and apparatus for measuring high-frequency electrical characteristics of electronic device, and method for calibrating apparatus for measuring high-frequency electrical characteristics - Google Patents
Method and apparatus for measuring high-frequency electrical characteristics of electronic device, and method for calibrating apparatus for measuring high-frequency electrical characteristics Download PDFInfo
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R35/00—Testing or calibrating of apparatus covered by the other groups of this subclass
- G01R35/005—Calibrating; Standards or reference devices, e.g. voltage or resistance standards, "golden" references
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R27/00—Arrangements for measuring resistance, reactance, impedance, or electric characteristics derived therefrom
- G01R27/28—Measuring attenuation, gain, phase shift or derived characteristics of electric four pole networks, i.e. two-port networks; Measuring transient response
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/28—Testing of electronic circuits, e.g. by signal tracer
- G01R31/282—Testing of electronic circuits specially adapted for particular applications not provided for elsewhere
- G01R31/2822—Testing of electronic circuits specially adapted for particular applications not provided for elsewhere of microwave or radiofrequency circuits
Definitions
- the present invention relates to a method and apparatus for measuring high-frequency electrical characteristics of an electronic device, such as a filter, a coupler, a balun, or the like, or an impedance device, such as a chip inductor, a chip capacitor, or the like. More specifically, the present invention relates to a method for correcting a measurement error in measuring scattering parameters or the impedance of the electronic device using a measuring device, such as a network analyzer or the like.
- a planar transmission line (such as a microstrip line or a coplanar waveguide) is connected to the network analyzer via coaxial cables or the like, and the electronic device is brought into contact with the planar transmission line to make a measurement.
- a scattering parameter matrix of the impedance device serving as a test object it is necessary to identify error factors of a measurement system and to remove the effects of the error factors from the measurement results. This is referred to as correction or calibration.
- FIGS. 1 and 2 show respective measurement systems using a network analyzer and corresponding error models for use in SOLT calibration and TRL calibration.
- An electronic device 1 serving as a test object is connected to a transmission line provided on the top surface of a measuring fixture 2 .
- Two ends of the transmission line on the measuring fixture 2 are connected to measurement ports of the network analyzer, which is not shown, via coaxial cables 3 .
- S 11A , S 21A , S 12A and S 22A are scattering parameters of the transmission line including the test object
- E DF , E RF , and E SF are scattering parameters on one measurement port side
- E LF and E TF are scattering parameters on the other measurement port side.
- S 11A , S 21A , S 12A and S 22A are scattering parameters of the test object, e 00 , e 01 , e 01 and e 11 are scattering parameters on one measurement port side, and f 00 , f 10 , f 01 and f 11 are scattering parameters on the other measurement port side.
- SOLT calibration As shown in FIG. 3 , three types of connectors 4 including a short (0 ⁇ ), an open ( ⁇ ), and a termination (50 ⁇ ) are used, and the ports are directly connected to each other to achieve a through state.
- a planar transmission line for use in measuring a surface-mounted device is, unlike a waveguide or a coaxial transmission line, unable to achieve a satisfactory “open” or “termination”, and it is thereby practically impossible to perform SOLT calibration.
- measured values obtained by measurements are not characteristics of the test object 1 alone, but are composite characteristics of the test object 1 and the measuring fixture 2 to which the test object is connected. It is thus impossible to measure characteristics of the test object alone.
- a (through) transmission line 5 a whose ports are directly connected to each other
- various types of transmission lines 5 c and 5 d of different lengths.
- the transmission lines 5 a to 5 d it is relatively easy to fabricate transmission lines whose scattering parameters are known.
- the total reflection is achieved by shorting, it is relatively easy to estimate characteristics thereof. Therefore, these transmission lines are sufficient to perform calibration. Basically, it is possible to measure the characteristics of the test object 1 alone.
- the through transmission line 5 a is a so-called zero-through.
- the test object is connected in series with the measuring fixture 2 whose length is greater than the through transmission line 5 a by the length of the test object, and a measurement is made.
- the coaxial connectors 3 are common among the transmission lines 5 a to 5 d , and coaxial pins are in contact and connected to the transmission lines serving as the standards, thereby avoiding the effects of variations in connector measurements. Structurally, however, it is difficult to ensure a sufficient pressing load at the connections, and hence the coaxial pins may be damaged. Since the connections are unstable, calibration becomes also often unstable. The higher the measurement frequency, generally the thinner the transmission lines and the coaxial pins. Depending on the positioning repeatability thereof, measurement variations may become larger.
- Japanese Unexamined Patent Application Publication No. 6-34686 discloses a method for calibrating a network analyzer having two test terminals to be connected to a test object via a strip line. That is, a first calibration measurement is made to measure transmission and reflection parameters of the microstrip line whose propagation constant is unknown, which is connected between the two test terminals in a reflection-free manner. Three further calibration measurements are made using the same line and three calibration standards realized with reflection-symmetric and reciprocal discontinuous objects disposed at three different positions on the line.
- the three types of standards are realized by changing the state of the transmission line to three states. This way, the standards are connected only once. With this method, compared with TRL calibration, the number of times the standards are connected is reduced, and hence measurement errors in the calibration operation are reduced in number.
- Measured values obtained by connecting a test object are not characteristics of the test object alone, but are composite characteristics of the test object and the strip line to which the test object is connected. It is thus impossible to measure the characteristics of the test object alone.
- the present invention solves these problems in TRL calibration and SOLT calibration and provides a highly accurate method for measuring high-frequency electrical characteristics of an electronic device, which is not affected by characteristic variations in connections.
- the present invention also provides a highly accurate apparatus for measuring high-frequency electrical characteristics of an electronic device.
- the present invention further provides a highly accurate method for calibrating a high-frequency electrical characteristic measuring apparatus.
- An embodiment of the invention provides a method for measuring high-frequency characteristics of an electronic device.
- the method includes a step of preparing a transmission line whose electrical characteristics per unit length are known, the transmission line including a plurality of signal conductors disposed with a space therebetween, and at least one ground conductor; a step of connecting the signal conductors and the ground conductor to associated measurement ports of a measuring device; a step of measuring, at least three points in the longitudinal direction of each signal conductor, an electrical characteristic in a connection state where each signal conductor is connected to the ground conductor; a step of measuring electrical characteristics in a through state between the signal conductors; a step of obtaining error factors of a measurement system including the transmission line on the basis of measured values in the connection state, measured values in the through state, and the electrical characteristics of the transmission line; a step of connecting the electronic device to be measured between the signal conductors or among the signal conductors, and the ground conductor, and measuring electrical characteristics; and a step of removing the error factors of the measurement system
- a further embodiment of the invention provides a technique for removing errors of a measurement system including the transmission line and the like, in a method including the steps of connecting a test object in series among signal conductors and a ground conductor of a transmission line serving as a measuring fixture or connecting the test object among the signal conductors and the ground conductor, measuring reflection and transmission parameters and the like, and obtaining, on the basis of the measured values, electrical characteristics including an impedance, quality parameter, or the like.
- This embodiment is based on the knowledge that, in the measurement of errors of the measurement system, it is possible to achieve a satisfactory short-circuited state of the transmission line.
- a short standard is employed as a calibration standard (standard). This is because, since a short-circuited state is substantially equivalent to a total reflection state, the effects of terminated ends of the signal conductors can be avoided. In the frequency range where the transmission line serving as an object operates in TEM single mode, characteristics in the short-circuited state are substantially not affected by a dielectric, and it is possible to estimate electrical characteristics of the transmission line with high accuracy using an electromagnetic field simulation.
- a parameter that limits the accuracy of simulated transmission line characteristics is a dielectric constant. It has been confirmed that there is only a negligible change in the calculation results of the reflection characteristics in a short-circuited state when the dielectric constant is changed. It can be said that there is no harm in assuming that the simulation results are physical true values to be used in calibration.
- the width of the transmission line is sufficiently smaller than the wavelength of a measured signal, it can be regarded that no big error will be introduced by using ⁇ 1 (reflection parameter of an ideal short) as a short characteristic.
- a transmission line including a plurality of signal conductors with electrical characteristics uniform in the longitudinal direction is shorted at least three points on the transmission line, thereby identifying error factors of a measurement system.
- a short standard is connected between each of the signal conductors and the ground conductor. Specifically, the short standard is connected to a test object measurement position, and a measurement is made. Next, the short standard is connected to a point spaced away from the test object measurement position by L 1 , and a measurement is made. Then, the short standard is connected to a point spaced away from the test object measurement position by L 2 , and a measurement is made. If the characteristics of the transmission line are unknown, a fourth measurement is made at another point.
- the short standard refers to electrically shorted devices in general.
- the short standard is not limited to chip devices and includes metal pieces or tools.
- the short standard has a shortlength of contact in the longitudinal direction of the transmission line, such as at the edge of a knife. If the short standard is ideal, the reflection parameter is ⁇ 1 (total reflection). In reality, however, the short standard has a certain amount of inductance, and it is thus necessary that the inductance be known. In a microwave band, compared with an open state, it is generally relatively easy to achieve an almost ideal short-circuited state. If high measurement accuracy is required, the inductance of the short standard shall be obtained with a simple simulation or the like.
- error factors of the measurement system are identified in a through state between the signal conductors.
- a through state for example, a through chip whose transmission parameters have no directivity is connected in series.
- the ports are connected with each other to achieve a through state.
- the characteristics of the through chip need not be known.
- a chip resistor whose resistance is unknown can be employed.
- such a chip resistor shall not have directivity.
- the through chip is not limited to a chip device and includes any device as long as the device has no signal transmission directivity.
- Measurement Step Measurement of Test Object
- the electrical characteristics of an electronic device serving as a test object are measured by connecting the electronic device in series between the signal conductors of the transmission line, or simultaneously connecting the electronic device in series between the signal conductors and to the ground conductor.
- true values of the electrical characteristics of the test object can be calculated.
- the signal conductors and the ground conductor are shorted in the calibration step. However, it is not always necessary to short the signal conductors and the ground conductor. It is sufficient that the signal conductors be connected to the ground conductor so as to achieve some sort of a reflection state.
- the port 1 and the port 2 may be connected to each other using a through chip or the like. A signal is transmitted via the through chip to the port 2 and is not completely reflected at the open end of the signal conductor. Thus, the level of the returning signal can be reduced.
- the RRRR calibration implemented in the above-described manner has the following features.
- TRL calibration transmission lines of different lengths serving as standards are necessary, and it is also necessary that connections between the transmission lines and coaxial cables have equivalent electrical characteristics.
- RRRR calibration one and the same transmission line is employed not only in calibration, but also in measurement. It is thus unnecessary to reconnect the transmission line, and the RRRR calibration is not affected by variations in characteristics of the transmission line, the connectors, and the connections.
- a device to be measured is not limited. In particular, the accuracy of measuring an electronic device with an impedance higher than the characteristic impedance of the transmission line is high.
- the length of the transmission line necessary for the measuring fixture is determined by the lower limit of the frequencies to be measured. In order to handle low frequencies, a long transmission line is necessary. However, a short transmission line is sufficient to handle high frequencies.
- Measurements for calibration are made by performing the measurement using the calibration standard (e.g., the short standard) at a few points on the transmission line and the through measurement using an appropriate device.
- the calibration standard e.g., the short standard
- the number of points at which the measurement using the calibration standard is performed and how far they are away from the test object measurement position are determined by the measurement frequency bandwidth and the upper frequency limit. It is sufficient that the through chip have no directivity, and the scattering parameters of the through chip may be unknown.
- the characteristics of the transmission line can also be obtained.
- the error factors of the measurement system can be obtained by connecting the calibration standard to three points. If the calibration standard is connected to four or more points, not only the error factors of the measurement system, but also the characteristics of the transmission line (dielectric constant, loss parameter, etc.) can be obtained. Therefore, even when the dielectric constant or loss parameter of a dielectric material for use in the transmission line fixture is unknown or even when the characteristics of a dielectric material in each lot vary, the characteristics of the transmission line fixture to be used can be accurately obtained, and highly accurate calibration can be performed without errors.
- transmission line fixtures made of a base material such as Teflon® or alumina have electrical characteristics that vary only slightly, and it is easy to obtain the physical true values of the electrical characteristics.
- these transmission line fixtures are expensive.
- transmission line fixtures made of a base material including a general resin such as an epoxy resin or the like are inexpensive.
- material characteristics of these transmission line fixtures vary greatly, and the dielectric constant and loss parameter thereof also vary.
- the calibration standard is connected to four or more points to obtain transmission line characteristics. In this way, the electrical characteristics of a test object can be measured with high accuracy without being affected by variations in the transmission line characteristics.
- the characteristic impedance of the transmission line need not be known. However, in order to measure the impedance or the like, it is necessary that the characteristic impedance of the transmission line be known. This may be obtained with a known method, such as calculating the impedance with a simulation or by using a value actually measured with a time domain reflectory method.
- the error factors are determined using, not only the measurement results obtained in the short-circuited state, but also the measurement results obtained using the series-connected through chip whose transmission parameters have no directivity.
- the test object can also be regarded as one type of through chip. Therefore, the measurement using the through chip may be omitted, and the error factors can be determined using the results of measuring the test object and the measurement results obtained in the short-circuited state.
- test object is not limited to a device with two terminals.
- An electronic device with three or more terminals can be used as long as the device has no directivity between the ports.
- error factors up to each test object measurement position can be removed.
- errors between the test object measurement positions that is, in the case of two ports, error factors between points on the two ports in contact with a test-object electrode, are not taken into consideration.
- the maximum error is stray capacitance between the signal conductors. If there is stray capacitance, a measurement of the test object yields a value including the stray capacitance, which thereby causes an error.
- the electrical characteristics are measured in a state (open state) where nothing is connected to the signal conductors, and the stray admittance is obtained from the measurement results.
- the short standard is connected to the transmission line.
- the influence of the residual inductance of the short standard may be great, and the signal conductors and the ground conductor may not be sufficiently shorted (signal passes from one port to the other and the total reflection cannot be achieved).
- the calibration standard be brought near (but not in contact with) the transmission line, and the stray capacitance generated between the transmission line and the calibration standard and the residual inductance of the calibration standard will form a series resonance state.
- the impedance of a portion connected to the calibration standard is 0 ⁇ , that is, an ideal short-circuited state is achieved. In other words, even at high frequencies where a satisfactory short standard is not realized, the same advantage as that of using a satisfactory short standard can be achieved.
- the capacitor may be brought into contact (completely connected) with the transmission line to produce series resonance.
- the transmission line of the present examples a transmission line including signal conductors and a ground conductor disposed on the same plane.
- the calibration standard or the test object can be easily connected to the signal conductors and the ground conductor at the same time. Since the calibration standard or the test object can be vertically pressed against the transmission line at the time of calibration or measurement, a sufficient pressing load can be easily ensured, and hence the contact easily becomes stable.
- a coplanar waveguide or a slot line may be used as the transmission line.
- the coplanar waveguide includes signal conductors and ground conductors having the signal conductors therebetween, and the signal conductors and the ground conductors are disposed on the same plane.
- the coplanar waveguide is suitable for the measurement of high-frequency characteristics up to 10 GHz.
- the slot line includes signal conductors and a ground conductor, which are disposed on the same plane with a space therebetween.
- the slot line is suitable for the measurement of high-frequency characteristics at 10 GHz or higher.
- the calibration standard be connected to positions at which the phase difference between the positions is between 70° and 145°.
- the phase difference between the positions at which the calibration standard is connected is between 70° and 145° in order to enhance the calibration accuracy.
- the phase difference between the connection positions is set as described above, the frequency range that can be handled by a pair of calibration standards becomes quite narrow, though the calibration accuracy becomes high.
- the setting of the positions at which the calibration standard is connected is very easy, and when the measured data in the calibration is put to full use, the number of times the calibration standard is measured is not greatly increased, even in the case of broadband measurement, which thereby presents no practical problem.
- FIG. 1 is a diagram showing a measurement system using a network analyzer and an error model of SOLT calibration.
- FIG. 2 is a diagram showing a measurement system using a network analyzer and an error model of TRL calibration.
- FIG. 3 is a diagram showing SOLT calibration.
- FIG. 4 is a diagram showing TRL calibration.
- FIG. 5 is a plan view of a high-frequency electrical characteristic measuring apparatus showing an example of RRRR calibration according to an embodiment of the present invention.
- FIG. 6 is a front view of the high-frequency electrical characteristic measuring apparatus in the calibration example shown in FIG. 5 .
- FIG. 7 is a plan view of the high-frequency electrical characteristic measuring apparatus in a through measurement according to the example.
- FIG. 8 is a diagram of an error model for use in the RRRR calibration according to the example.
- FIG. 9 includes plan views of the high-frequency electrical characteristic measuring apparatus according to the example, which is measuring a test object.
- FIG. 10 is a flowchart of an example of the RRRR calibration according to the example.
- FIG. 11 is a flowchart of another example of the RRRR calibration according to the present invention.
- FIG. 12 is a view showing the effects of stray capacitance generated between transmission lines.
- FIG. 13 is a diagram of high-frequency characteristics of a chip inductor measured using the RRRR calibration according to the embodiments of the present invention.
- FIG. 14 is a plan view of the high-frequency electrical characteristic measuring apparatus showing another example of the RRRR calibration according to the present invention.
- FIGS. 15 ( a ) and ( b ) are schematic diagrams showing examples in which series resonance is produced between a calibration standard and a transmission line.
- FIG. 16 is a plan view showing an example of a transmission line with three ports.
- FIG. 17 is a plan view of an example in which a slot line is used as a transmission line.
- FIGS. 5 to 9 show a first embodiment according to the present invention.
- a calibration standard to be measured is a short standard 10 in all cases, and a measuring fixture 11 (transmission line 12 ) to be used is the same fixture in all cases.
- measurements are performed at three or more points on the transmission line 12 disposed on the measuring fixture 11 .
- calibration performed on the side of a port 1 (connector 11 a ) will be described.
- the same operation is also done on the side of a port 2 (connector 11 b ).
- the measuring fixture 11 includes, as shown in FIGS. 5 and 6 , two signal conductors 12 a and 12 b disposed on a straight line on the top surface of a fixture board 11 c .
- Ground conductors 12 c have the signal conductors 12 a and 12 b therebetween in the width direction, with a space therebetween, and the signal conductors 12 a and 12 b and the ground conductors 12 c are disposed on the same plane on the fixture board 11 c .
- a ground conductor 12 d is disposed on the back surface of the fixture board 11 a .
- the connectors 11 a and 11 b are connected to coaxial cables 14 and to measurement ports 21 to 24 of a network analyzer 20 , which is an example of a measuring device.
- Signal lines 14 a of the coaxial cables 14 are fixed by soldering, welding, or the like to the signal conductors 12 a and 12 b in order to eliminate connection variations.
- the measurement ports 21 and 24 are connected via the coaxial cables 14 to the signal conductors 12 a and 12 b , and the measurement ports 22 and 23 are connected to the ground conductors 12 b.
- a pusher 15 for pressing the short standard 10 against the transmission line 12 and a mechanism 16 for allowing the pusher 15 to freely move along the transmission line 12 are provided above the measuring fixture 11 .
- a knife-edge-shaped conductor fixed to the tip of the insulating pusher 15 is used as the short standard 10 .
- the short standard 10 is connected to a point at which a first electrode is connected to measure a test object (measurement point 1 in FIG. 5 : P 1 , hereinafter referred to as a “test object measurement point”), and thereafter a measurement is made, where S 11M1 is the measurement result.
- ⁇ A1 be a true value of a reflection parameter at the measurement point.
- ⁇ A1 is a true value of the short standard.
- the short standard 10 is connected to a position on the signal conductor 12 a distant from the test object measurement point by L 1 toward the port 1 (measurement point 2 : P 2 ), and thereafter a measurement is made, where S 11M2 is the measurement result.
- ⁇ A2 is the true value of the reflection parameter of the short standard 10 at the measurement point 2 .
- the test object measurement point be a reference plane, and the true value of the reflection parameter is expressed as shown in equation 1. Because an electromagnetic wave entering the port 1 is completely reflected by the short standard 10 , the distance of the wave transmitted through the transmission line is shorter by 2 L 1 in a round trip than that in the case where the short standard 10 is connected to the test object measurement point.
- ⁇ is the transmission degree [U/mm] of the transmission line per unit length
- ⁇ is a phase constant [rad/mm] of the transmission line
- the short standard 10 is connected to a position on the signal conductor 12 a distant from the test object measurement point by L 2 toward the port 1 (measurement point 3 : P 3 ), and thereafter a measurement is made, where S 11M3 is the measurement result.
- S 11M3 is the measurement result.
- the transmission line characteristics ⁇ are unknown, not only error parameters, but also the transmission line characteristics ⁇ can be obtained by shorting the transmission line at four points using the short standard.
- the transmission line characteristics ⁇ include two unknown values, namely, the transmission degree ⁇ : and the phase parameter ⁇ . Since the transmission line characteristics ⁇ are represented by a complex number in which a real number portion corresponds to the transmission degree ⁇ and an imaginary number portion corresponds to the phase parameter ⁇ , the transmission line characteristics ⁇ can be obtained as one unknown value.
- the transmission line characteristics can be explicitly calculated using the following equation.
- the transmission line characteristics cannot be calculated using the following equation, and it is thus necessary to obtain the transmission line characteristics by iterative calculations or the like.
- ⁇ [[ ⁇ ( S 11M3 2 ⁇ 2 S 11M2 S 11M3 ⁇ 3 S 11M2 2 +8 S 11M1 S 11M2 ⁇ 4 S 11M1 2 ) S 11M4 2 +( ⁇ 2S 11M1 S 11M3 2 +(8S 11M2 2 ⁇ 12S 11M1 S 11M2 +8S 11M1 2)S 11M3 ⁇ 2S 11M1 S 11M2 2 )S 11M4 +( ⁇ 4S 11M2 2 +8S 11M1 S 11M2 ⁇ 3S 11M1 2 )S 11M3 2 ⁇ 2S 11M1 2 S 11M2 S 11M3 +S 11M1 2 S 11M2 S 11M3 +S 11M1 2 S 11M2 S 11M3 +S 11M1 2 S 11M2 S 11M3 +S 11M1 2 S 11M2 2 ⁇ 1/2 +(S 11M3 ⁇ S 11M2 )S 11M4 ⁇ S 11M1 S 11M3 +
- a measurement is made in a through state (ports are directly connected to each other), as shown in FIG. 7 .
- a device appropriate for establishing a connection between the ports (hereinafter referred to as a through chip) 13 is connected in series between the signal conductors 12 a and 12 b .
- Measured values are such that S 11MT and S 22MT are reflection parameters, and S 21MT and S 12MT are transmission parameters.
- the electrical characteristics of the through chip 13 need not be known.
- a chip resistor whose resistance is unknown may serve as the through chip 13 .
- the transmission parameters of the through chip 13 shall not have directivity. Since the transmission parameters do not have directivity on the basis of the reciprocity theorem, unless a special material, such as a ferrite under the DC magnetic field, is used, this condition is usually automatically satisfied.
- FIG. 8 shows an error model of RRRR calibration. This is the same as an error model that has been used in TRL calibration ( FIG. 2 ).
- S 11M and S 21M are estimated values of a reflection parameter and a transmission parameter, respectively
- S 11A , S 21A , S 12A and S 22A are true values of scattering parameters of a test object.
- There are eight error coefficients E XX and F XX . Since the scattering parameter measurement is the ratio measurement, seven error factors are sufficient to be defined. Specifically, let E 21 1.
- a test object 17 is connected to the transmission line 12 , and characteristics of the test object 17 are measured.
- the test object 17 is picked up using a chip mounter or the like to bring the test object 17 into contact with the test object measuring position on the transmission line 12 , and the electrical characteristics (S 11M , S 21M , S 12M , and S 22M ) are measured.
- the test object 17 has two terminals, as shown in portion (a) of FIG. 9
- the test object 17 is connected in series between the signal conductors 12 a and 12 b .
- the test object 17 has three terminals or four terminals, as shown in portion (b) of FIG.
- the test object 17 is connected among the signal conductors 12 a and 12 b and the ground conductors 12 c .
- the measurement method according to the present invention is applicable not only to a two-terminal electronic device but also to an electronic device, such as a filter, with three or more terminals.
- Equations for removing the effects of errors are given below. In order to remove the effects of error factors, these equations are calculations based on the reflection parameters in the case of two-port measurement. Alternatively, calculations may be based on the outputs of four ports of the network analyzer. In the case of three or more ports, equations similar to these equations may be used, or the effects of error factors may be removed with a circuit simulation technique. In short, any known technique may be selected. In equations 14, D 2 is an intermediate variable.
- FIG. 10 is a flowchart of an example of an RRRR calibration method.
- a measuring device When calibration starts, a measuring device is connected via coaxial cables to a measuring fixture (step S 1 ).
- the signal conductor 12 a and the ground conductors 12 c are shorted by the short standard 10 at a first position, which is the open end of the signal conductor 12 a (step S 2 ).
- the first position may be in the vicinity of the test object measurement position or another position.
- the reflection parameter (S 11M1 ) on the port 1 side is measured (step S 3 ).
- the signal conductor 12 a and the ground conductors 12 c are shorted by the short standard 10 at a second position (step S 4 ), and the reflection parameter (S 11M2 ) on the port 1 side is measured (step S 5 ).
- the signal conductor 12 a and the ground conductors 12 c are shorted by the short standard 10 at a third position (step S 6 ), and the reflection parameter (S 11M3 ) on the port 1 side is measured (step S 7 ).
- step S 8 the signal conductor 12 a and the ground conductors 12 c are again shorted by the short standard 10 at a fourth position (step S 8 ), and the reflection parameter (S 11M4 ) on the port 1 side is measured (step S 9 ).
- step S 10 the transmission line characteristics ⁇ on the port 1 side are calculated (step S 10 ).
- the other signal conductor 12 b and the ground conductors 12 c are shorted by the short standard 10 at a fifth position, which is the open end of the signal conductor 12 b (step S 11 ).
- the fifth position may be in the vicinity of the test object measurement position or another position. While the short standard 10 is connected, the reflection parameter (S 22M1 ) on the port 2 side is measured (step S 12 ).
- the signal conductor 12 b and the ground conductors 12 c are shorted by the short standard 10 at a sixth position (step S 13 ), and the reflection parameter (S 22M2 ) on the port 2 side is measured (step S 14 ).
- the signal conductor 12 b and the ground conductors 12 c are shorted by the short standard 10 at a seventh position (step S 115 ), and the reflection parameter (S 22M3 ) on the port 2 side is measured (step S 16 ).
- step S 17 If the transmission line characteristics are unknown, the signal conductor 12 b and the ground conductors 12 c are again shorted by the short standard 10 at an eighth position (step S 17 ), and the reflection parameter (S 22M4 ) on the port 2 side is measured (step S 18 ). On the basis of the reflection parameters, the transmission line characteristics ⁇ on the port 2 side are calculated (step S 119 ). When the transmission line characteristics ⁇ are known, steps S 17 to S 19 are unnecessary.
- the through chip 13 is connected in series between the signal conductors 12 a and 12 b (step S 20 ), and the transmission parameters (S 21MT and S 12MT ) are measured (step S 21 ).
- the error coefficients are calculated using the measured reflection parameters, transmission parameters, and transmission line characteristics ⁇ , using equations 10 to 13 (step S 22 ).
- the test object is connected to the measuring fixture (step S 23 ), and the reflection parameters and the transmission parameters (S 11M , S 21M , S 12M , and S 22M ) of the test object in the forward and reverse directions are measured (step S 24 ).
- the effects of errors are removed from the measured values using equations 14 (step S 25 ), and the error-removed results (true values of the test object) are displayed on a display and the test object is selected (step S 26 ). Thereafter, steps S 23 to S 26 are repeated until the measurement of all the test objects is completed (step S 27 ).
- the RRRR calibration ends.
- FIG. 11 is a flowchart of an additional step of detecting poor contact on the basis of the transmission parameter, in the process of deriving the error coefficients in FIG. 10 . Although detection of poor contact only at the first position is shown here, similar processing is performed at the other positions.
- the measuring device is connected via the coaxial cables to the measuring fixture (step S 1 ).
- the signal conductor 12 a and the ground conductors 12 c are shorted by the short standard 10 at the first position (step S 2 ), and, simultaneously, the through chip 13 is connected between the signal conductors 12 a and 12 b (step S 30 ).
- the reflection parameter (S 11M1 ) and the transmission parameter (S 21M1 ) on the port 1 side are measured (step S 31 ). It is determined whether the measured transmission parameter is sufficiently small (step S 32 ). If the transmission parameter is not sufficiently small, it is determined that there is poor contact, and the processing from step S 2 onward is again repeated. In contrast, if the transmission parameter is sufficiently small, it is determined that the contact is satisfactory, and a measurement is made at the second position.
- the short standard 10 is measured at the test object measurement point on the transmission line 12 and at a point 5 mm away from the test object measurement point. If the transmission line 12 has low loss, the only difference between the measurement results at the two points is the phase.
- the wavelength be 30 mm (the wavelength of a 1-GHz electromagnetic wave in a vacuum), and a difference of 5 mm in position corresponds to a difference of 10 mm in position in a round trip.
- the wavelength be 10 mm (the wavelength of a 3-GHz electromagnetic wave in a vacuum)
- a difference of 5 mm in position calibration cannot be performed properly at the frequency of the 10-mm wavelength.
- phase difference between the calibration standards the higher the accuracy of calibration.
- the frequency range that can be handled by a pair of calibration standards becomes narrow, and it thus becomes necessary to measure many calibration standards in order to perform broadband measurement.
- TRL calibration using the phase difference between calibration standards to perform calibration as in the RRRR calibration, it is necessary to have a phase difference of 20° to 30° or greater between calibration standards in order to achieve a satisfactory measurement accuracy.
- the second position at which the short standard is measured, at which the phase at the upper limit measurement frequency is about 145°, is obtained. Specifically, the second position is obtained using the following equation:
- ⁇ [rad/mm] is a phase constant
- L[mm] is a position at which the short standard is measured.
- the third position at which the short standard is measured is set to 2 L[mm]
- the fourth position at which the short standard is measured is set to 4 L[mm].
- the n-th position at which the short standard is measured is set to 2 n ⁇ 2 L[mm].
- the RRRR calibration is performed using the results of measurements made at the first, second, and third positions at which the short standard is measured.
- the results of measurements made at the first, third, and fourth positions at which the short standard is measured are used.
- the results of measurements made at the first, (n+1)-th, and (n+2)-th positions at which the short standard is measured are used. Accordingly, the phase difference between the positions at which the short standard is measured remains between 70° and 145°.
- a series method to which the RRRR method belongs is supposed to be able to perform high impedance measurement using a high-isolation measuring fixture. If a measuring fixture made of a high dielectric material, such as a glass epoxy material, or a thick measuring fixture of 1.6 mm or the like is used, the stray capacitance between the ports becomes higher, whereas the isolation becomes lower. This problem is alleviated by fabricating a thin measuring fixture made of a low dielectric material, such as Teflon®. However, when this alleviation is not sufficient, or when a measuring fixture with satisfactory characteristics cannot be used because the cost is too high (Teflon® boards are generally expensive), the error can be corrected mathematically.
- a high dielectric material such as a glass epoxy material, or a thick measuring fixture of 1.6 mm or the like
- the stray admittance of the measurement results is obtained on the basis of the results of measurement of the measuring fixture alone (open state), and the effects of the stray admittance are mathematically removed from the results of measuring the test object.
- Z c be the impedance of the RRRR-calibrated measuring fixture
- Z M be the impedance obtained by RRRR-calibrating the test object measurement results
- Z L is obtained using the following equation. If Z C is excessively high, it may be possible that the dynamic range of the measurement system becomes narrow and the measurement results vary greatly. In order to avoid such a problem, a measuring fixture with a very low isolation is not used. Generally, the satisfactory results may be obtained with the processing described above.
- the description of the RRRR method has been given mainly in terms of the scattering parameters
- the description of the open calibration has been given using the impedance.
- the impedance and the scattering parameters are interconvertible physical quantities.
- Z 0 be the characteristic impedance of the transmission line
- S 11 be the reflection parameter of the scattering parameters
- S 21 be the transmission parameter of the scattering parameters.
- the scattering parameters and the impedance Z can be converted using the following equations. Although two equations are given, basically the same results are obtained with either equation.
- a 10-nH chip inductor (wire-wound chip inductor) with a size of 1 mm ⁇ 0.5 mm is measured within the range from 100 MHz to 20 GHz, the results of which are shown in FIG. 13 .
- the true values of the test object can be measured by the RRRR calibration.
- the directivity-free through chip 13 is connected in series between the signal conductors 12 a and 12 b , the transmission parameters S 21MT and S 12MT in the forward and reverse directions are measured, and the ratio S 21MT /S 12MT is obtained, thereby determining the relationship among the error coefficients. If a test object has no directivity, the through chip measurement may be omitted, and the error coefficients can be determined using the results of measuring the test object.
- test objects including a filter, a coupler, a balun, a capacitor, a resistor, and a coil have no directivity.
- these test objects may also be regarded as types of through chips.
- the transmission parameter ratio S 21M /S 12M is obtained on the basis of the results of measuring the test object. This ratio replaces S 21MT /S 12MT , and hence the relationship among the error coefficients can be determined using equation 12.
- the open end of the signal conductor 12 a and the open end of the signal conductor 12 b are connected to each other via a through chip 19 , and, in this state, the calibration standard 18 is connected to at least three points on the transmission line 12 to perform RRRR calibration.
- the through chip 19 may be a device similar to the through chip 13 in the through measurement (see FIG. 7 ) or a short chip such as the short standard 10 .
- the signal is transmitted through the through chip 19 toward the port 2 and is absorbed on the port 2 side, thereby reducing the level of the signal returning to the port 1 .
- the RRRR calibration can be used as a method for identifying the error factors of the fixture.
- Recent network analyzers are equipped with a function (de-embedding function) for automatically removing the effects of given errors from the measurement results when the error coefficients of the fixture or the like are given. Since there is no method to obtain errors of the fixture, this function is not actually often used. However, when this function is combined with the RRRR calibration according to the present invention, this function becomes a very convenient function.
- De-embedding is a technique for mathematically removing known error factors and is easily implemented using a transfer matrix.
- a scattering parameter matrix of the obtained error factors of the fixture are converted into a transfer matrix, and an inverse matrix of the transfer matrix is calculated.
- E ⁇ 1 and F ⁇ 1 be inverse matrices of the transfer matrices on the sides of the ports 1 and 2 , respectively.
- a transfer matrix of the error factors at each port of the fixture is EF.
- A be a transfer matrix of the device.
- the results of measuring the device including the fixture using the network analyzer calibrated up to the tips of the coaxial cables include errors at each port superimposed onto the characteristics of the device, and hence E ⁇ A ⁇ F
- the RRRR calibration procedure requiring the highly accurate positioning of the calibration standard or the like is performed in a laboratory environment to determine error factors of each fixture with high accuracy.
- devices can be mass-produced using a fixture whose error factors are already known. Needless to say, the errors of the fixture are removed by de-embedding the error factors obtained in the laboratory.
- the RRRR method can be exercised without preparing means for positioning the calibration standard with high accuracy in each process. This is advantageous in terms of cost and production control.
- the measuring device is equipped with a computer and dedicated software.
- the computer automatically calculates the calibration standard characteristics at each position on the basis of equations 1 to 3, which can be used in calibration calculations using equations 10 to 13.
- the network analyzer is enabled to automatically estimate the values of the calibration standard and perform RRRR calibration.
- the residual inductance of the calibration standard may have a large influence due to high frequencies, and, even when the calibration standard is connected to the transmission line, the transmission line may not be sufficiently shorted (signal passes from one port to the other and no total reflection is achieved).
- a calibration standard 26 may be placed in contact with the transmission line 12 , thereby producing series resonance.
- the calibration standard 26 may be a capacitor with a very small capacitance.
- the impedance of a portion in contact with the calibration standard is 0 ⁇ , that is, an ideal short-circuited state is achieved. In other words, even at high frequencies where a satisfactory short standard is not obtained, the same advantage as that of using a satisfactory short standard can be achieved.
- FIG. 16 shows an example of a measuring fixture with three ports.
- reference numeral 30 denotes a measuring fixture
- reference numerals 31 , 32 , 33 denote three signal conductors disposed on the top surface of the measuring fixture 30
- reference numeral 34 denotes ground conductors disposed so as to have the signal conductors 31 , 32 , 33 therebetween
- reference numeral 35 , 36 , 37 denote connectors disposed at ends of the measuring fixture 30 .
- First ends of the signal conductors 31 , 32 , 33 are adjacent to one another and face one another, and second ends of the signal conductors 31 , 32 , 33 are connected to the connectors 35 , 36 , 37 , respectively.
- a calibration standard is connected between each of the signal conductors 31 , 32 , 33 and the ground conductors 34 , and calibration is performed. Thereafter, a test object 38 is connected among the signal conductors 31 , 32 , 33 or among the signal conductors 31 , 32 , 33 and the ground conductors 34 , and electrical characteristics are measured.
- the electrical characteristics of the test object 38 with three or more terminals can be measured.
- a slot line 40 may be used.
- the slot line 40 includes signal conductors 41 and 42 and a ground conductor 43 , which are disposed on the same plane with a space therebetween.
- a test object 44 is connected between the signal conductors 41 and 42 or among the signal conductors 41 and 42 and the ground conductor 43 , and electrical characteristics are measured.
- the high-frequency electrical characteristic measuring method according to the present invention is not limited to the above embodiments.
- the measuring device of the present invention is not limited to the network analyzer. Any device that can measure high-frequency electrical characteristics can be used as the measuring device.
- the calibration standard is measured at the test object measurement position, the calibration standard need not be measured at the test object measurement position. In this case, three or more measurements of the calibration standard are all expressed using equation 1.
- the transmission line is not limited to the planar transmission line.
- a transmission line with an arbitrary structure can be used as long as the calibration standard can be connected thereto, the through chip can be connected in series therewith, and the test object can be connected between the signal conductors or among the signal conductors and the ground conductor(s).
- measuring fixtures with one port to three ports have been described by way of example, a measuring fixture with four or more ports can be used. In this case, similar calibration and measurement can be performed.
- a high-frequency electrical characteristic measuring method has the following advantages.
- a transmission line for use in calibration is the same as a transmission line for use in measuring a test object, the method is less likely to be influenced by variations of the transmission line. Connections between the transmission line and a measuring device are fixed in calibration and in the actual measurement, and there is no need to establish a reconnection. There will be no calibration failures or the like due to poor contact with the transmission line or the like.
- the method is highly effective in accurately measuring scattering parameters or the impedance of an electronic device such as a filter, a coupler, a balun, or the like, or an impedance device such as a chip inductor, a chip capacitor, or the like.
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Abstract
Description
ΓA2=ΓA1α−2L
ΓA3=ΓA1α2L
ΓA4=ΓA1α−2L
ξ=α−2exp(j2β) [Eq. 4]
ΓA2=ΓA1ξL
ΓA3=ΓA1ξL
ΓA4=ΓA1ξL
L1:L2:L3=1:2:3
L1:L2:L3=1:2:4
ξ=[[{(S 11M3 2+(2S 11M1−4S 11M2)S 11M3+4S 11M1 S 11M2−3S 11M1 2)S 11M4 2
+((2S11M2−4S11M1)S11M3 2+(4S11M2 2−4S11M1S11M2+4S11M1 2)S11M3
−4S11M1S11M2 2+2S11M1 2S11M2)S11M4+(4S11M1S11M2−3S11M2 2)S11M3 2
+(2S11M1S11M2 2−4S11M1 2S11M2)S11M3+S11M1 2S11M2 2}1/2
+(S11M3−2S11M2+S11M1)S11M4+(S11M2−2S11M1)S11M3+S11M1S11M2]
/((2S11M2−2S11M1)S11M4+(2S11M1−2S11M2)S11M3)]1/L1 [Eq. 8]
ξ=[[{(S 11M3 2−2S 11M2 S 11M3−3S 11M2 2+8S 11M1 S 11M2−4S 11M1 2)S 11M4 2
+(−2S11M1S11M3 2+(8S11M2 2−12S11M1S11M2+8S11M1 2)S 11M3
−2S11M1S11M2 2)S11M4+(−4S11M2 2+8S11M1S11M2−3S11M1 2)S11M3 2
−2S11M1 2S11M2S11M3+S11M1 2S11M2 2}1/2+(S11M3−S11M2)S11M4
−S11M1S11M3+S11M1S11M2]
/{(2S11M2−2S11M1)S11M4+(2S11M1−2S11M3)S11M3}]1/L1 [Eq. 9]
E21=1
E 12=(E 21 E 12)/E 21
F 12=√{square root over ((E 21 E 12)(F 21 F 12)S 21MT /S 12MT)}{square root over ((E 21 E 12)(F 21 F 12)S 21MT /S 12MT)}
F 21=(F 21 F 12)/F 12 [Eq. 13]
—Measurement Results—
E·A·F
E −1 ·E·A·F·F −1 =A
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PCT/JP2004/019086 WO2005101034A1 (en) | 2004-04-02 | 2004-12-21 | Method and instrument for measuring high-frequency electric characteristic of electronic component, and method for calibrating high-frequency electrical characteristic measuring instrument |
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